KR20240011989A - A fire proof door with a thermal deformation preventing devices - Google Patents

Abstract

The present invention relates to a fire door with a thermal deformation prevention function. Specifically, the present invention relates to a fire door with a thermal deformation prevention function. In detail, a thermal deformation prevention member is formed on a fire door made of a fire door frame and an exterior plate to prevent thermal deformation and distortion of the fire door due to high temperature in the event of a fire, thereby preventing the fire from occurring at the point of occurrence. It is about a fire door with a thermal deformation prevention function that prevents flames and heat from spreading to the other side.
The present invention draws and processes part of the vertical frame of a fire door, which is a thin plate, and molds a fire cap directly into the vertical frame, thereby eliminating the need to weld a separate fire cap, thereby reducing assembly defects, thermal deformation, and rigidity of the weld zone due to welding of the fire cap. It has the effect of preventing vulnerability.
In addition, the present invention replaces the punching process of cutting a part of a fire door or fire door frame, which is a thin plate, with a burring process to form a burring reinforcement on the edge of the cylinder installation groove, thereby preventing a decrease in the rigidity of the fire door frame and preventing thermal deformation due to high heat. There is an effect.
In addition, the present invention adds a reinforcing pad to the horizontal frame where the hinge is installed in the fire door, adds a hinge pin support plate to support the hinge pin, and forms a fastening reinforcement portion by burring the fastening hole of the horizontal frame that fastens the horizontal frame and the hinge. This has the effect of preventing the hinges or horizontal frames from being twisted or deformed due to weakening of the fire door's strength due to its own weight or the hot heat in the event of a fire.

Description

{A fire proof door with a thermal deformation preventing devices}

The present invention relates to a fire door with a thermal deformation prevention function. Specifically, the present invention relates to a fire door with a thermal deformation prevention function. In detail, a thermal deformation prevention member is formed on a fire door made of a fire door frame and an exterior plate to prevent thermal deformation and distortion of the fire door due to high temperature in the event of a fire, thereby preventing the fire from occurring at the point of occurrence. It is about a fire door with a thermal deformation prevention function that prevents flames and heat from spreading to the other side.

In general, fire doors are not only a component of a fire compartment to prevent the spread of fire in the event of a fire in a building, but are also a major element of evacuation stairs for human safety and are required to be installed in buildings over a certain size. It refers to a door that is legally required to use non-combustible materials to separate each compartment and prevent the spread of fire in the event of a fire. Most fire doors are made of iron to meet these requirements.

The fire door as described above is manufactured through a process such as assembling four frames in a square shape, joining steel sheet panels to the front and rear of the frame, fixing a hinge connected to the door frame on the side, and inserting a cylinder bundle. .

Conventionally, the four fire door frames were joined by welding as shown in Figure 1. However, since the thickness of the steel plate as a material is thin and durability is required, the welding work requires careful attention, so most fire doors or fire door frames are manufactured. In the field, skilled welders are required to do the welding work, but it is becoming more and more difficult to supply and demand manpower. In addition, precision is reduced due to manual work, and welding, which is a manual process for making fire doors, acts as a major obstacle to the automated process, resulting in mass production. It is becoming a factor that limits production.

In addition, the fire door functions to block the spread of flame and heat at the beginning of a fire by rotating and opening in conjunction with the door frame, but in the event of a large fire or when exposed to high temperature heat for a long period of time, a thin metal frame or a thin metal base is used as shown in Figure 11. A distortion phenomenon occurs in the fire door 110 due to thermal deformation of the exterior plate, causing a problem in which flames and high heat within the fire occurrence point leak and spread through the gap 120.

Conventionally, in order to prevent such thermal deformation distortion of the fire door, a fire cap device was installed at the position where the vertical surface of the fire door and the door frame come into contact with each other, as shown in Figure 12, to increase resistance and prevent the fire door from being distorted. This fire cap device includes a fire cap 40 installed on the vertical plane corresponding to the side where the door hinge is installed in the fire door 20, and a door frame 30 installed at a position corresponding to the installation position of the fire cap. It consists of a fire prevention pin (50) that goes in and out of the fire cap according to the opening and closing operation of the fire door.

However, in order to install the above-described fire cap device, conventionally, a mounting hole 21 having a predetermined size is drilled in the vertical surface of the fire door, then the fire cap 40 is inserted from the outside to the inside of the mounting hole, and then the edges are welded. It was fixed in such a way that a fire prevention pin (50) was fastened to the door frame corresponding to the installation position of the fire prevention cap using a screw method.

However, since the fire door 20 is a thin plate, welding defects occur in the process of welding the fire cap 40 to the fire door 20, and even after welding, the installation position of the fire cap 40 is distorted due to thermal deformation of the plate, thereby preventing the fire later. It may be difficult to connect with the pin 50, and when exposed to high heat caused by a fire, the welded part of the fire cap 40 becomes vulnerable before other parts, so the fire cap properly performs its function of preventing thermal deformation of the fire door. There is a problem that cannot be done.

In addition, in order to prevent thermal deformation of the fire door, as shown in Patent Registration No. 10-1065400, an automatic safety pin installed inside the fire door is activated according to the operation of the heat detection fuse, which is a sensing medium that blows when the internal heat rises above a certain temperature in the event of a fire. Prior art has been known in which the locking groove is automatically inserted and fastened to physically suppress the distortion of the fire door (suppressing gap opening).

However, the above fire door distortion prevention technology inevitably requires the provision of automatic safety pins and locking recesses including heat-sensing fuses and springs. The structure is complex, which not only makes assembly and installation difficult, but also increases the overall price of fire doors due to the increase in parts. This results in a decrease in competitiveness, and productivity is poor as additional processes must be performed to install these parts (heat-sensing fuse, automatic safety pin, spring, locking inlet) on fire doors and door frames, and in addition, corrosion due to surrounding moisture. Malfunction of the heat-sensing fuse frequently occurs due to foreign substances or foreign substances, making it difficult to ensure operational stability.

In addition, door handles that rotate to the left and right are generally installed on the inside and outside of the fire door, and in the middle of the inside and outside door handles, when the door handle is rotated, the lock appears on the outside of the side of the door in contact with the door frame. It is configured to be coupled with a door lock cylinder that controls the open/closed state of the door.

However, in order to install the door lock cylinder and lock on the fire door, a part of the fire door or fire door frame is cut to form a cylinder installation groove. Due to this cylinder installation groove, the rigidity of the fire door or fire door frame is lowered, preventing thermal deformation due to high heat. There is a problem of becoming more vulnerable.

Additionally, hinges are generally installed on the upper and lower portions of the fire door so that they can rotate in the opening/closing direction of the fire door, and a support member fitted to the hinge is fixedly installed on the door frame where the fire door is installed.

In such a fire door, if the hinge is installed on the frame that makes up the fire door without a separate structure, the hinge may be distorted by the fire door's own weight or its strength will be weakened by the hot heat in the event of a fire, causing the hinge to be twisted or deformed, causing problems in opening and closing the fire door. There is a serious problem that the operation is not performed stably and the stability in use is greatly reduced.

Prior Art 1: Patent Registration No. 10-1065400

In order to solve the above problems, the present invention allows the fire door frame, which consists of a horizontal frame and a vertical frame, to be transported in a disassembled state and assembled directly on site, and the horizontal frame and vertical frame can be simply connected to each other without welding or fastening members. The technical task is to provide a fire door frame that is easy to assemble and a fire door equipped with the same.

In addition, the present invention aims to prevent poor assembly, thermal deformation, and weakening of the rigidity of the welded part due to the welded part by installing the fireproof cap to the fireproof door without welding in a fireproof cap device installed on a fire door made of thin plate material.

In addition, the present invention aims to prevent thermal deformation due to high heat by preventing a decrease in the rigidity of the fire door or fire door frame due to a cylinder installation groove formed by cutting a part of the fire door or fire door frame, which is a thin plate.

In addition, the technical task of the present invention is to prevent the frame where the hinge is installed in a fire door from being twisted or deformed due to weakening of the strength of the frame due to the fire door's own weight or heat during a fire.

The present invention according to one embodiment is a fire door including a horizontal frame 10 and a vertical frame 50, in which a fire cap 54 is installed on the vertical frame 50 on the side where the door hinge is installed. It is formed by molding itself, and is characterized by including a fixing pin 310 inserted into the fire cap 54 in the door frame 300 corresponding to the installation position of the fire cap 54.

In addition, in the present invention, a cylinder installation groove 55 is formed in the vertical frame 50 on the side where the door cylinder is installed, and a cylinder installation groove reinforcement portion 56 is formed on the edge of the cylinder installation groove 55. It is characterized by being formed by burring itself.

In addition, in the present invention, cylinder fastening hole protrusions 58 for screwing the door cylinder above and below the cylinder installation groove 55 of the vertical frame 50 are formed by burring the vertical frame 50 itself, and the cylinder fastening hole is formed by burring the vertical frame 50 itself. It is characterized by a threaded portion being formed on the inner peripheral surface of the protrusion 58.

In addition, in the present invention, the outer bent portions 11 of the upper and lower horizontal frames 10 are formed upright on both sides of the bottom surface 16 so that the cross section of the horizontal frame 10 forms a “└┘” shape, and the hinge 150 A hinge installation end (17) is formed on one side of the outer bent portion (11) so that it can be installed,

The hinge 150 includes a hinge wing portion 151 installed on the bottom surface 16 of the horizontal frame 10, and a hinge fixing portion 152 installed on the hinge installation end 17 of the outer bent portion 11. Including,

The thickness of the hinge wing portion 151 is smaller than the thickness of the hinge fixing portion 152,

A characteristic feature is that a reinforcing pad 160 is added between the bottom surface 16 of the horizontal frame 10 and the hinge wing portion 151.

In addition, a plurality of bolt insertion holes 154 for coupling with the reinforcement pad 160 and the horizontal frame 10 are formed in the hinge wing portion 151 of the hinge 150 of the present invention, and the reinforcement pad 160 has a hinge A plurality of bolt through holes 161 are formed for coupling with the wing portion 151 and the horizontal frame 10, and the horizontal frame 10 has a plurality of bolt fastening holes 18 for coupling with the reinforcement pad 160. is formed,

At least one of the bolt insertion hole 154 or the bolt through hole 161 is formed as a long hole to easily adjust the position at which the hinge 150 is installed on the horizontal frame 10.

In addition, the bolt fastening hole 18 of the horizontal frame 10 of the present invention is characterized in that it is formed through a burring process to form a burring protrusion, and a threaded portion is formed on the inner peripheral surface of the burring protrusion.

In addition, the present invention provides a hinge pin support plate ( 170) is additionally added.

In the present invention, a fire door frame can be simply assembled by combining the insertion portion formed in the horizontal frame and the coupler formed in the vertical frame without welding or a separate fastening member, and the fire door frame can be transported in a disassembled state to be used on site. Direct assembly is possible, and it has the effect of simply assembling the horizontal frame and vertical frame without using any welding or fastening members.

In addition, the present invention draws and processes part of the vertical frame of the fire door, which is a thin plate, and molds the fire cap directly into the vertical frame, thereby eliminating the need to weld a separate fire cap, thereby eliminating assembly defects, thermal deformation, and welding parts due to welding of the fire cap. It has the effect of preventing stiffness and weakness.

In addition, the present invention replaces the punching process of cutting a part of a fire door or fire door frame, which is a thin plate, with a burring process to form a burring reinforcement on the edge of the cylinder installation groove, thereby preventing a decrease in the rigidity of the fire door frame and preventing thermal deformation due to high heat. There is an effect.

In addition, the present invention adds a reinforcing pad to the horizontal frame where the hinge is installed in the fire door, adds a hinge pin support plate to support the hinge pin, and forms a fastening reinforcement portion by burring the fastening hole of the horizontal frame that fastens the horizontal frame and the hinge. This has the effect of preventing the hinge or horizontal frame from being twisted or deformed due to weakening of the fire door's strength due to its own weight or the hot heat in the event of a fire.

1 is an explanatory drawing of a fire door according to the present invention.
Figure 2 is a diagram showing an embodiment of an insertion part of a horizontal frame according to the present invention.
Figure 3 is a diagram showing an embodiment of a coupling part of a vertical frame according to the present invention.
Figure 4 is a diagram showing a state in which the insertion part of the horizontal frame and the coupling part of the vertical frame are combined according to the present invention.
Figure 5 is a cross-sectional view showing an internal protruding end and an external protruding end formed on the steel panel of the fire door according to the present invention.
FIG. 6 is an explanatory diagram of the horizontal frame applied to FIG. 5.
Figure 7 is a view explaining the reinforcing bent portion of the horizontal frame and the vertical frame according to the present invention.
Figure 8 is a view explaining another embodiment of the reinforcing bent portion of the horizontal frame and the vertical frame according to the present invention.
Figure 9 is a view explaining the installed state of the locking portion and fixing portion of the fire door according to the present invention.
Figure 10 is a diagram explaining the structure and operation of the locking portion and fixing portion of the fire door according to the present invention.
Figure 11 is a diagram explaining a state in which a conventional fire door is thermally deformed and distorted.
Figure 12 is a diagram explaining a state in which a conventional fire cap is installed.
Figure 13 is a view explaining a state in which a fire cap is molded on a vertical frame in the present invention.
Figure 14 is a view explaining the drawing forming method of the fire cap of the vertical frame in the present invention.
Figure 15 is a view explaining the fire cap of the vertical frame and the fixing pin of the door frame in the present invention.
Figure 16 is a view explaining the cylinder installation groove and the cylinder installation groove reinforcement portion formed in the vertical frame in the present invention.
Figure 17 is a diagram illustrating a method of forming a cylinder installation groove reinforcement portion of a vertical frame in the present invention.
Figure 18 is a diagram explaining an exploded perspective view of the hinge and reinforcement pad in the present invention.
Figure 19 is a diagram explaining the hinge pin support plate in the present invention.
Figure 20 is a view explaining a state in which the hinge pin support plate is assembled to the hinge in the present invention.
Figure 21 is a diagram illustrating a state in which the hinge pin is supported by the hinge pin support plate in the lower horizontal frame in the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention may be subject to various changes and may have various forms, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Referring to FIG. 1, a fire door frame 100 according to an embodiment of the present invention is constructed by combining two horizontal frames 10 and two vertical frames 50 to form a square frame. Each horizontal frame 10 and vertical frame 50 is provided with a “ㄷ” shaped channel shape by bending a steel plate.

According to Figure 2, a steel plate is bent at both ends of the horizontal frame 10 to form an insertion portion 20. The insertion portion 20 includes an insertion body 21 forming a ladder shape with upper and lower beams, and an insertion body 21 ) is provided with a locking protrusion (22) formed on both upper edges of the insertion body (21) and a fitting protrusion (23) formed at the lower center of the insertion body (21).

According to FIG. 3, coupling portions 60 are formed at both ends of the vertical frame 50, and the coupling portion 60 includes an “ㄱ”-shaped protrusion-shaped coupling hole 61 and a square-shaped fitting groove 62. Equipped with

Figure 4 shows a state in which the insertion portion 20 of the horizontal frame 10 and the coupling portion 60 of the vertical frame 50 are coupled, in which the insertion body 21 of the horizontal frame 10 is connected to the vertical frame ( It is slide inserted at one end of the couplers 61 of the insert body 21, and the locking protrusion 22 of the insertion body 21 is inserted so that it protrudes from the other end of the coupler 61, so that the insertion body 21 has a locking protrusion 22. ) to prevent it from leaving after insertion.

In addition, while the insertion body 21 of the horizontal frame 10 is slide-inserted at one end of the couplers 61 of the vertical frame 50, the fitting protrusion 23 of the insertion body 21 is connected to the coupler 60. It is inserted into the fitting groove 62, and the fitting protrusion 23 is formed to protrude obliquely to prevent movement in the direction opposite to the insertion direction, so that the fitting protrusion 23 of the insertion body 21 is inserted into the fitting groove of the coupling portion 60. After insertion in (62), escape is prevented.

In addition, the insertion body 21 of the horizontal frame 10 has a ladder shape with upper and lower beams so that both edges of the insertion body 21 are inclined, and the vertical frame 50 coupled to the insertion body 21 is formed. The spheres 61 are also formed to be inclined to correspond to the edges on both sides of the insertion body 21, and the two edges of the insertion body 21 and the coupling spheres 61 are coupled by an interference fit method.

In this way, the edges on both sides of the insertion body 21 and the couplers 61 are pressed together in an inclined state, thereby creating the effect of the insertion body 21 being wedge-coupled with the couplers 61, and also the insertion body ( Even if there is a shape error or manufacturing error of the insertion body 21 or the coupler 61, the coupling of the insertion body 21 and the coupler 61 can be facilitated, and the center of the insertion body 21 and the coupler 61 ), the effect of facilitating the coupling of the insertion body 21 and the coupler 61 occurs even if the centers are mismatched.

Due to this structure, the present invention facilitates the coupling or assembly of the insertion body 21 and the coupler 61, and the oblique interference fit of the insertion body 21 and the coupler 61, and the insertion body 21. Since the insertion body 21 and the coupler 61 are prevented from being separated by the blocking protrusion 22 and the fitting protrusion 23, the horizontal frame 10 and the vertical frame 50 can be easily connected without separate welding or fastening members. They are easily connected to each other, making assembly easy, and they are prevented from coming off even after assembly, resulting in great durability.

In addition, the present invention forms an outer bent portion 11 in the horizontal frame 10 as shown in FIG. 4 and an inner bent portion 51 in the vertical frame 50 to form the horizontal frame 10 and the vertical frame 50. ) increases the rigidity. At this time, in the present invention, the horizontal frame 10 bends the insertion portion 20 in the opposite direction to the outer bent portion 11, and the vertical frame 50 bends the inner bent portion 51 in the direction of the coupling portion 60. By bending, difficulty in assembling the horizontal frame 10 and the vertical frame 50 due to the bent portions 11 and 51 is prevented, and both the insertion portion formed in the horizontal frame and the coupler formed in the vertical frame are connected to the frame 100. The fire door frame of the present invention is formed to protrude inside the rectangular frame forming the frame so that it does not interfere with the insertion portion or joint when assembling the steel sheet panel or installing the fire door frame. The fire door frame of the present invention facilitates the assembly of the frame itself and facilitates the assembly of the fire door or the installation of the door frame. There is an effect.

Figure 5 is a cross-sectional view showing an internal protruding end and an external protruding end formed on a steel panel of a fire door.

In the present invention, the horizontal frame 10 and the vertical frame 50 are assembled and combined to form a rectangular frame 100, and then first and second steel panels are installed on the front and back of the frame 100. 210 and 220) are attached to manufacture a fire door, and to increase the rigidity of the steel plate panel, external protrusions and internal protrusions can be formed as shown in FIG. 5.

The external protrusion is formed by bending one end of the first panel 210 and one end of the second panel 220 to protrude out of the frame 100 in the width direction of the fire door 200.

Specifically, the first panel 210 has an external protruding surface 211 that protrudes in the width direction of the fire door 200 and protrudes outward from the vertical frame 50-1, and the external protruding surface 211 is bent at 180 degrees. This forms a “U”-shaped external bent portion 212, thereby forming an external bent surface 213 facing inside the vertical frame 50-1.

In addition, the second panel 220 is bent to closely surround the vertical frame 50-1 to form one end in the thickness direction of the fire door 200, and one end is bent at 90 degrees so that it protrudes in the width direction of the fire door 200. It is bent to form an external extension surface 221 that protrudes outward from the vertical frame 50-1, and the external extension surface 221 is inserted between the “U”-shaped external bent portions 212 to form the first panel 210. ) is in close contact with the external protruding surface 211 and the external bending surface 213.

The internal protrusion is formed by bending the other end of the first panel 210 and the other end of the second panel 220 to protrude into the frame 100 in the width direction of the fire door 200.

Specifically, the first panel 210 is bent to closely surround the vertical frame 50-2 to form the other side end in the thickness direction of the fire door 200, and the other side end of the first panel 210 is the fire door 200. It protrudes inward in the width direction of the fire door 200 to form an internal protruding surface 214, and the internal protruding surface 214 is bent at 180 degrees to form a “U” shaped internal bending portion 215, which forms an internal protruding surface 214 in the width direction of the fire door 200. It forms an internal bending surface 216 facing.

In addition, the second panel 220 forms the other side end in the thickness direction of the fire door 200, and is bent at 90 degrees so that the other side end protrudes inward in the width direction of the fire door 200 to form an internal extension surface 222, The inner extension surface 222 is inserted between the “U” shaped inner bent portions 215 and comes into close contact with the inner protruding surface 214 and the inner bent surface 216 of the first panel 210.

Due to the internal and external protrusions configured in this way, the first and second panels (210, 220) can be assembled and joined without welding or separate fastening members, and the “U”-shaped coupling structure at both ends of the first and second panels As a result, the joint rigidity increases, which has the effect of preventing twisting and increasing durability of the fire door.

Additionally, the external protrusion of the fire door has a sealing effect that closes the gap between the fire door and the door frame or the gap between the fire door and other fire doors when the fire door contacts the door frame or another fire door.

Additionally, heat-resistant paint or heat-resistant coating may be added to the first and second panels or the vertical and horizontal frames of the fire door to enhance heat-resistant performance.

For example, a phosphate layer formed on a galvanized steel sheet with an adhesion amount of 1 to 5 g/m2 based on one side of the steel sheet; And a coating layer coated with a heat-resistant coating composition at an adhesion amount of 1 to 5 g/m2 based on one side of the steel plate is added, and the heat-resistant coating composition includes 50 to 70% by weight of silicone resin, 7 to 15% by weight of phosphoric acid ester compound, and colo. It contains 10 to 20% by weight of silica, 5 to 25% by weight of a bromine compound, and 0.1 to 0.5% by weight of a silane coupling agent.

In addition, instead of coating the first and second panels or the vertical and horizontal frames of the fire door with heat-resistant coating or heat-resistant paint, heat-resistant steel, which has heat resistance, can be used as the steel sheet material itself.

For example, heat-resistant steel has C: 0.08% to 0.13% by mass; Si: 0.15% to 0.45%; Mn: 0.1% to 1.0%;; Ni 0.01% to 0.5%; Cr: 10.0% to 11.5%; Mo:0.3% to 0.6%; V: 0.10% to 0.25%; Nb: 0.01% to 0.06%; It consists of N: 0.015% to 0.07%, B: ≤ 0.005%, and Al: ≤ 0.04%, and the remainder is steel containing Fe and inevitable impurity elements.

Alternatively, a temperature change coating layer can be added to the first and second panels of the fire door to enable visual identification in the event of a fire.

For example, a color conversion film that changes color according to changes in temperature is attached to the outer surface of the first and second panels, and a coating layer of transparent heat-resistant paint is painted on the outer surface of the color film, so that the first and second panels When heat is applied, the color changes, creating a visual contrast with before the color change, allowing users to easily recognize the occurrence of a fire.

The color conversion film changes color at a specific temperature by mixing one or more of metal complex dye, cholesteric liquid crystal, metamocolor, crystal violet lactone, Ag2HgI4, and Cu2HgI4 in a certain ratio and mixing it with a pigment of the desired color. Let's do it.

In the case of forming an internal protrusion protruding into the inside of the fire door at the other end of the first and second panels 210 and 220 of the fire door as shown in FIG. 5, the second protrusion installed at the other end of the first and second panels 210 and 220 The second vertical frame 50-2 is formed to be narrower than the first vertical frame 50-1 installed at one end of the first and second panels 210 and 220.

In Figure 5, the first and second panels 210 and 220 of the fire door have a thickness of about 1 mm, and the inner protrusion of the fire door is in close contact with the inner protruding surface 214, the inner extending surface 222, and the inner bending surface 216. The thickness of the internal protrusion is at least 3 mm, so that the overall width of the second vertical frame 50-2 is about 5 mm smaller than that of the first vertical frame 50-1.

In addition, the gap between the couplers 61 of the first vertical frame 50-1 is about 25 mm, and the gap between the couplers 61 of the second vertical frame 50-2 can be adjusted to about 20 mm. there is.

In addition, due to the thickness of the internal protrusion of the fire door, the second vertical frame 50-2 is installed on the other side of the fire door to have a deviation (e) from the thickness center line of the fire door, and the deviation (e) may be about 5 mm. , Accordingly, the coupler 61 and the fitting groove 62 formed in the second vertical frame 50-2 are also installed to have a deviation e from the thickness center line of the fire door.

In this case, the coupler 61 and the fitting groove 62 of the first vertical frame 50-1 are installed to match the thickness center line of the fire door, and the coupler 61 of the second vertical frame 50-2 And since the fitting groove 62 is installed to have a deviation (e) from the thickness center line of the fire door, the horizontal coupling hole 61 and the fitting groove 62 of the first and second vertical frames 50-1 and 2 are coupled to each other. The insertion portion 20 of the frame 10 must also be installed to have a deviation e as shown in FIG. 6.

In FIG. 6, the first insertion portion 20-1 formed at one end of the horizontal frame 10 is installed so that the center of the insertion body coincides with the width direction center line of the horizontal frame 10, and the second insertion portion 20-1 formed at the other end The insertion portion 20-2 is formed so that the center of the insertion body has a deviation e from the width direction center line of the horizontal frame 10. Additionally, the bottom width of the insertion body of the first insertion part 20-1 may be set to approximately 22 mm, and the bottom width of the insertion body of the second insertion part 20-2 may be set to approximately 20 mm.

Figures 7 and 8 are diagrams illustrating the reinforcing bends of the horizontal frame and the vertical frame according to the present invention. Figure 7 is a diagram showing the formation of the square reinforcing bends 12 in the horizontal frame 10 and the vertical frame 50. , FIG. 8 is a view of another embodiment of FIG. 7 in which triangular reinforcing bends 13 and 53 or round bends 14 and 54 are formed on the horizontal frame 10 and the vertical frame 50.

As shown in Figures 7 and 8, a square reinforcement bend 12, a triangular reinforcement bend 13, or a round bend 14 is formed in the longitudinal direction in the horizontal frame 10, but in the opposite direction to the outer bend 11. A square reinforcement bend 52, a triangular reinforcement bend 53, or a round bend 54 is formed on the vertical frame 50 in the longitudinal direction, but in the opposite direction to the inner bend 51, By increasing the longitudinal rigidity of the horizontal frame 10 and the vertical frame 50 while allowing the reinforcing bends 12, 13, 14, 52, 53, and 54 to protrude toward the inside of the fire door, they can be used when assembling steel sheet panels or installing fire door frames. It has the effect of not interfering with poetry.

Figures 9 and 10 are diagrams explaining the locking and fixing parts for opening and closing a fire door. Since the fire door is intended to prevent the spread of flame and smoke in the event of a fire, it is usually fixed in an open state for the convenience of users. It is necessary to ensure that it closes automatically only in case of fire.

Figure 9 shows a state in which the fire door 200 is normally open. A locking portion 400 is installed on the fire door 200 and a fixing portion 500 is installed on the wall 700 to prevent the fire door 200 from being caught. The unit 400 is fixed to the fixing unit 500 on the wall to maintain the open state of the fire door, and when the control unit 600 detects smoke or fire, it transmits a release signal to the fixing unit 500 wired or wirelessly to secure the fixing unit ( When 500 pushes the fire door 200 while releasing the locking portion 400, the fire door 200 rotates around the hinge 240 to close the exit.

10, the locking part 400 of the present invention will be described in detail. The locking part 400 is installed at the rear of the fire door 200 facing the wall 700, and has a large release force due to the release force of the fixing part 500. The fire door 200 is installed at a distance from the center of rotation so that a rotational moment occurs in the fire door.

The locking portion 400 of the present invention includes a cone-shaped locking head 410, a locking groove inclined surface 1 (421), and a locking groove inclined surface 2 (422), and a locking groove inclined surface 1 (421) and a locking groove inclined surface 2 (422). It is configured to include a locking groove 420 forming a “V” shaped groove, and a body portion 430 having a cylindrical shape and having male threads formed on the outer circumferential surface.

The locking head 410 of the locking part 400 is inserted and coupled between the fixtures 521 of the fixing part 500, which will be described later, and is formed in a cone shape for easy insertion.

The locking groove 420 of the locking part 400 is configured to prevent the locking head 410 from being separated by being caught by the fixture 521 of the fixing part 500, which will be described later. It is formed to facilitate insertion and fixation in the “V” shaped groove formed by the locking groove slope 1 (421) and the locking groove slope 2 (422), while the inclination angle of the locking groove slope 2 (422) is similar to the locking groove slope 1 (421). It is formed to be smaller than the inclination angle of (based on the horizontal center line of the locking part), so that the locking head 410 can easily be separated from the fixture 521 of the fixing part 500 by the release force of the fixing part 500.

The body portion 430 of the locking portion 400 is formed with male threads on the outer circumferential surface so as to be screwed to the fire door 200, and the body portion 430 of the locking portion 400 is connected to the wall ( 700), and is installed at a distance from the center of rotation of the fire door 200 so that a large rotational moment occurs in the fire door due to the release force of the fixing part 500.

9 and 10, if the fixing part 500 of the present invention is described in detail, when the fire door 200 is fully opened and located inside the wall step 710, the locking part 400 corresponding to the fire door 400 is installed. A fixing part 500 is installed at the location.

The fixing unit 500 of the present invention is installed in a fixing unit box 510 having an internal space in a rectangular shape installed on a wall, and is installed in the inner space of the fixing unit box 510 and the engaging head 410 of the engaging unit 400. ), a fixing member 520 coupled to the fixing unit box 510, a release member 530 installed in the inner space and applying a release force to the locking head 410 of the locking part 400, and a fixing member ( The operating direction of the release member 520 and the operating direction of the release member 530 are installed at right angles to each other.

The fixing member 520 of the present invention includes a fixture 521 coupled to the locking head 410 of the locking portion 400, a fixture spring 522 that elastically supports the fixture 521, a fixture 521, and a fixture. It includes a fixture installation hole 523 where a spring 522 is installed, and the fixture 521 has a “V” shape with a tip corresponding to the locking groove 420 of the locking portion 400, and the fixture spring. (522) acts as an elastic force to push the fixture 521 toward the locking groove 420, and the fixing members 520 of this configuration are arranged up and down or left and right, or four fixing members 520 are spaced at 90-degree intervals. can be placed.

The release member 530 of the present invention includes a release rod head 531 in contact with the locking head 410 of the locking portion 400, a rod-shaped release rod 532 supporting the release rod head 531, and It includes an electromagnet 533 that applies electromagnetic force to the release rod 532 to cause it to slide, and an electromagnet spring 534 that applies an elastic force to pull the release rod 532.

The release rod head 531 has a plate disk shape with a large area, so that the electromagnetic force of the release rod 532 is well transmitted to the locking head 410 even if there is a positional deviation from the locking head 410.

Explaining the operating process of the fixing part 500 of the present invention, in normal times, the fire door 200 is completely open and the fire door is located inside the wall step 710, and in this case, the locking part 400 installed on the fire door is caught. The head 410 is inserted and coupled between the fixtures 521 of the fixing member 520, and the fixture 521 is pressed by the fixture spring 522 to maintain close coupling with the locking groove 420 of the locking portion 400. Thus, the fire door 200 remains open.

When a fire occurs and heat or smoke is detected, the control unit 600 transmits a release signal wired or wirelessly to the release member 530 of the fixing unit 500 to close the fire door 200, and accordingly, the release member 530 Apply a current to the electromagnet 533 to cause the release rod 532 to protrude while overcoming the elastic force of the electromagnet spring 534, and accordingly, the release rod head 531 at the tip of the release rod 532 is connected to the catching portion 400. Press and push the locking head 410 so that the locking head 410 is separated from the fixture 521.

When the locking portion 400 is released through this process, the fire door 200 rotates around the hinge 240 to close the exit. At this time, a separate auxiliary device such as a torsion spring may be added to the hinge 240 of the fire door 200 to maintain the closed state.

Next, the molding of the fire cap 54 on the vertical frame in the present invention will be explained through FIGS. 13 and 14.

In order to form the fire cap 54 in the vertical frame, a blank, which is a vertical frame steel plate, is placed between the die and the blank holder. The blank is introduced into the space formed inside the die by pressure using a punch and formed. At this time, the flange portion of the blank between the die and the blank holder is drawn while receiving compressive stress in the circumferential direction and tensile stress in the radial direction.

In this type of drawing forming, most of the side walls are formed due to the inflow effect at the flange area rather than the tension forming effect at the area in contact with the punch. Therefore, strain may be concentrated at the corners of the blank plate, causing necking, which may cause breakage in the final product.

In an embodiment of the present invention, in order to prevent fracture due to necking at the corner of the blank, the flange portion of the blank is heated by dividing it into a low-temperature region and a high-temperature region, and the low-temperature region can be processed as the corner portion.

In an embodiment of the present invention, drawing forming is performed by forming a blank with a plate thickness of 1.6 mm so that the shrinkage ratio is 1.2. In a die of 20 mm, the diameter Draw and form using a 19 mm punch. The holding force for holding the blank is 2400 kgf, lubrication is done by applying a lubricant with a viscosity of 60 mm ² /s to the surface of the blank, the punch insertion speed (Ps) is 10 mm/min, and the forming depth is 6 to 7 mm. As much as possible, the corner radius R of the punch was set to 10 mm.

Figure 15 is a view explaining the fire cap 54 of the vertical frame and the fixing pin 310 of the door frame in the present invention.

A fire cap device is installed at a position where the vertical frame 50 of the fire door and the door frame 300 come into contact with each other to increase resistance and prevent the fire door from being twisted. This fire cap device includes an insertion hole 217 installed on the vertical surface corresponding to the side where the door hinge is installed in the fire door, a fire cap 54 formed on the vertical frame 50, and the fire cap 54. It consists of a fixing pin 310 that is inserted into the inside and outside of the fire cap according to the opening and closing operation of the fire door when installed on the door frame 300 corresponding to the installation position. The fixing pin 310 includes a fixing pin head 311 inserted into the fire cap 54 and a screw portion 312 fixed to the door frame 300.

As in the present invention, the fire cap 54, which is formed directly on the vertical frame 50, does not require welding work as in the past, so problems such as poor welding or difficulty in combining with the fixing pin 310 due to thermal deformation do not occur. A plurality of fire cap devices of the present invention can be installed as needed.

The fire cap 54 of the vertical frame and the fixing pin 310 of the door frame configured in this way are in a state where the fire door is closed due to a fire and the fixing pin 310 is inserted into the fire cap 54 while in contact with the door frame. , Due to the bonding force between the fixing pin 310 and the fire cap 54, distortion of the door frame or fire door due to fire can be prevented.

Next, the cylinder installation groove reinforcement portion 56 formed in the vertical frame of the present invention and the method of forming it will be described through FIGS. 16 and 17.

Door handles that rotate to the left and right are installed on the inner and outer sides of the fire door, and in the middle of the inner and outer door handles, when the door handle is rotated, the lock appears on the outside of the side of the fire door in contact with the door frame to open and close the fire door. Since the door lock cylinder that controls the state is configured to be coupled, in order to install the door lock cylinder and lock on the fire door, a portion of the vertical frame 50 is cut to form a cylinder installation groove 55. This cylinder installation groove 55 ), there is a problem that the rigidity of the fire door or fire door frame decreases, making it more vulnerable to thermal deformation due to high heat.

Conventionally, in order to solve this problem, a separate reinforcement plate was added by welding or screwing, but in the present invention, as shown in FIG. 16, the vertical frame 50 itself is burred to form a cylinder installation groove on the edge of the cylinder installation groove 55. A reinforcement portion 56 is formed.

Figure 16(a) shows the cylinder installation groove 55 and the cylinder installation groove reinforcement portion 56 on the outside of the vertical frame 50, and Figure 16(b) shows the cylinder installation groove (56) on the inside of the vertical frame 50. 55) and the cylinder installation groove reinforcement portion 56 are shown.

The cylinder installation groove reinforcement portion 56 may be formed on the left and right side edges of the cylinder installation groove 55 with a protruding height of about 4 to 5 mm. If necessary, it may be formed on the upper and lower edges of the cylinder installation groove 55 or on the upper, lower, left, and right sides. Can be formed on any border.

In addition, cylinder fastening hole projections 58 for screwing the door cylinder above and below the cylinder installation groove 55 of the vertical frame 50 are formed through a burring process, and a threaded portion is formed on the inner peripheral surface of the cylinder fastening hole projection 58 to open the door. The cylinder is more stably fastened to the vertical frame, which further improves the fastening force of the door cylinder.

When explaining the burring processing of the cylinder installation groove reinforcement portion 56 through FIG. 17, first, a square groove with a length of 70 mm and a width of 15 mm is punched into the vertical frame 50. Afterwards, a square burring punch 70 with a length of 70 mm and a width of 25 mm and a tapered tip is positioned so that its center coincides with the square groove of the perforated vertical frame 50. Next, when the square burring punch 70 is pressed downward while supporting the perforated vertical frame 50 with a holder, the edge of the square groove is pushed downward due to the tapered shape of the burring punch 70, and the protrusion height is about 5 mm. The in-cylinder installation groove reinforcement portion 56 is formed on the left and right edges of the square groove, and an installation groove with a length of 70 mm and a width of 25 mm is formed.

Since the cylinder installation groove reinforcement portion 56 formed in this way is formed by molding the vertical frame 50 itself, the rigidity to prevent thermal deformation of the vertical frame is further increased compared to adding a separate reinforcing member, and also a separate reinforcement member is formed. There is no need for a process to fasten the reinforcing member.

Next, the hinge reinforcement pad of the present invention will be described with reference to FIG. 18. The fire door of the present invention is made of a heavy metal material so that it does not deform even when exposed to high temperatures and explosions caused by fire. Therefore, the hinge installed on a regular door has a significant weight, so there is a problem in that the hinge installed on a regular door is not durable and cannot support the load and is damaged.

In addition, the upper and lower horizontal frames 10 are formed upright on both sides of the bottom surface 16 so that the outer bent portion 11 has a cross-section of the horizontal frame 10 in a “└┘” shape, as shown in FIG. 18, and the hinge A hinge installation end 17 is formed on one side of the outer bent portion 11 so that 150 can be installed.

The hinge 150 of the present invention includes a hinge wing portion 151 installed on the bottom surface 16 of the horizontal frame 10, and a hinge fixing portion installed on the hinge installation end 17 of the outer bent portion 11. It includes (152), the thickness of the hinge wing portion 151 is about 5 mm, and the thickness of the hinge fixing portion 152 is about 12 mm.

However, the height of the outer bent portion 11 is about 13 mm, and the height of the outer bent portion 11 where the hinge installation end 17 is formed is about 8 mm, and the thickness of the hinge wing portion 151 is about 5 mm. , When the hinge 150 is installed on the hinge installation end 17, a gap of about 8 mm occurs between the bottom surface 16 of the horizontal frame 10 and the hinge wing 151, making bolt fixation impossible.

In order to reduce the gap between the bottom surface 16 of the horizontal frame 10 and the hinge wing 151, the hinge installation end 17 is formed to be large, so that the outer bent portion 11 is formed with the hinge installation end 17. The height can be lowered, but this reduces the rigidity of the horizontal frame 10. After adding steel plates to the front and rear of the upper and lower horizontal frames, respectively, attach the upper and lower parts of the steel plates to the walls of the upper and lower horizontal frames. There was a problem in that the height of the outer bent portion 11 could not be lowered because it had to be wrapped and fixed through a seaming operation.

To solve this problem, the present invention adds a reinforcement pad 160 between the bottom surface 16 of the horizontal frame 10 and the hinge wing portion 151.

The reinforcement pad 160 has a shape and size corresponding to the hinge wing portion 151 and has a thickness that offsets the gap between the bottom surface 16 of the horizontal frame 10 and the hinge wing portion 151, for example. It has a thickness of 8mm.

The material of the reinforcement pad 160 can be metal or synthetic resin, and preferably metal or synthetic resin with excellent heat resistance is used.

For example, the reinforcement pad 160 is made of super engineering plastic (SEP) with improved heat resistance, and super engineering plastic (SEP) is polysulfone (PSU) and polyphenylene sulfide (PPS). , polyether ketone (PEK), polyether ether ketone (PEEK), liquid crystalline polymer (LCP), liquid crystalline polyester (LCP), polytetrafluoroethylene ;PTFE), perfluoroalkoxy alkane (PFA), ethylene tetra fluoro ethylene (E/TFE), polyvinylidene fluoride (PVDF), etc., fluororesins, poly Crystalline SEPs such as polyether nitrile (PEN) and polyimide (PI), poly (aryl ether sulfone) (PAES), polysulfone (PSU), and polyether sulfone ( These super engineering plastics include amorphous SEPs such as polyether sulfone (PES), polyarylate (PAR), polyamide imide (PAI), and polyether imide (PEI). It is strong yet light, and has heat resistance, chemical resistance, and/or wear resistance.

In the present invention, a plurality of bolt insertion holes 154 for coupling with the reinforcement pad 160 and the horizontal frame 10 are formed in the hinge wing 151 of the hinge 150, and the reinforcement pad 160 has a hinge wing. A plurality of bolt through holes 161 are formed for coupling the portion 151 with the horizontal frame 10, and the horizontal frame 10 has a plurality of bolt fastening holes 18 for coupling with the reinforcement pad 160. is formed

At least one of the bolt insertion hole 154 or the bolt through hole 161 of the present invention is formed as a long hole, so that the position at which the hinge 150 is installed on the horizontal frame 10 can be easily adjusted.

In addition, the bolt fastening hole 18 of the horizontal frame 10 is formed through a burring process to form a burring protrusion, and a threaded portion is formed on the inner peripheral surface of the burring protrusion, so that the hinge 150 and the reinforcement pad 160 are connected to the horizontal frame with fastening bolts. The fastening force at (10) can be further increased.

Additionally, the present invention may further include a hinge pin support plate 170 as shown in FIGS. 19 and 20.

The hinge pin support plate 170 has a shape and size corresponding to the outline shape of the hinge fixing part 152 as shown in FIG. 19, and includes a support plate bottom surface 171 supporting the lower surface of the hinge fixing part 152, and It includes a support plate edge portion 172 in close contact with the side outline edge of the hinge fixing portion 152, and a hinge pin support groove on the bottom surface of the support plate 171 for supporting the hinge pin 330, which functions as the hinge rotation central axis. Support plate bolt holes 173 for fastening to 174 and the hinge fixing portion 152 are further formed, and a plurality of support plate bolt holes 173 may be formed as needed.

Figure 20 is a diagram showing a state in which the hinge pin support plate 170 is coupled to the hinge fixing part 152. The hinge pin support plate 170 has a support plate bottom surface 171 and a support plate edge portion 172 as possible. It is coupled so as to be in close contact with the hinge fixing part 152 at the maximum.

FIG. 21 is a diagram illustrating a state in which the hinge 150 is installed on the lower horizontal frame 10 and the hinge 150 is coupled to the door frame hinge 320 and the hinge pin 330 of the door frame 300.

The hinge pin support plate 170 is tightly coupled to the hinge fixing portion 152 of the hinge 150, so that the hinge pin 330 of the door frame hinge 320 is inserted into the hinge pin support plate (170) through the hinge pin insertion hole 155. It is in contact with the hinge pin support groove 174 of 170), and the door frame hinge 320 and the hinge fixing part 152 are installed to make surface contact with each other.

In this way, the load of the fire door is applied to the hinge 150 installed on the lower horizontal frame 10, and the fire door load is applied to the hinge pin support plate 170, the hinge fixing part 152, the hinge pin 330, and the door frame hinge 320. ) is transmitted through the path, and during this load transfer process, the support plate bottom surface 171 and the support plate edge portion 172 of the hinge pin support plate 170 are in close contact with the hinge fixing portion 152 as much as possible, so that the load is It is distributed throughout the hinge fixing part 152, and the door frame hinge 320 and the hinge fixing part 152 are in surface contact with each other, so the fire door load is distributed and supported not only by the hinge pin 330 but also by the door frame hinge 320. .

In addition, since the hinge wings 151 of the hinge 150 are coupled to the lower horizontal frame 10 through the reinforcement pad 160, the fire door load is distributed and supported by the hinge wings 151.

In this way, the hinge 150 of the present invention supports the fire door load distributed over the entire hinge 150 due to the reinforcement pad 160 of the hinge wing 151 and the hinge pin support plate 170 of the hinge fixing part 152. This has the effect of increasing the durability of the hinge.

Although the present invention has been described in detail through specific examples, this is for detailed explanation of the present invention, and the present invention is not limited thereto, and may be understood by those skilled in the art within the technical spirit of the present invention. It is clear that it can be modified or improved.

10: horizontal frame 11: outer bend
12: Square reinforcement bend 13: Triangular reinforcement bend
15: Installation groove 16: Bottom surface
17: Hinge installation end 18: Bolt fastening hole
20: Insertion part
20-1: first insertion portion 20-2: second insertion portion
21: Insertion body 22: Locking protrusion
23: insertion protrusion
50: vertical frame
50-1: first vertical frame 50-2: second vertical frame
51: inner bent part 52: square reinforcement bent part
53: Triangular reinforcement bend
54: Fire cap
55: Cylinder installation groove 56: Cylinder installation groove reinforcement part
57: Cylinder fastening hole 58: Cylinder fastening hole projection
59: Square hole
60: coupling part
61: Coupler
61-1: 1st coupler 61-2: 2nd coupler
62: Fitting groove
70: Burring punch
100: frame
150: Hinge 151: Hinge wing portion
152: Hinge fixing part 153: Fastening bolt
154: Bolt insertion hole 155: Hinge pin insertion hole
156: Support plate fastening hole
160: Reinforcement pad 161: Bolt through hole
170: Hinge pin support plate 171: Bottom surface of support plate
172: Support plate edge 173: Support plate bolt hole
174: Hinge pin support groove

200: fire door
210: first panel 211: external protruding surface
212: external bent part 213: external bent surface
214: internal protruding surface 215: internal bending surface
216: Internal bending surface 217: Insertion hole
220: second panel
221: external extension surface 222: internal extension surface
230: Hang part installer 240: Hinge
300: door frame
310: fixing pin 311: fixing pin head
312: threaded portion 313: nut
320: door frame hinge 330: hinge pin
400: latching part 410: latching head
420: Locking groove 430: Body part
500: fixing unit 510: fixing unit box
520: Fixing member 521: Fixture
522: fixture spring 523: fixture installer
530: Release member 531: Release rod head
532: release rod 533: electromagnet
534: Electromagnet spring
600: Control unit 700: Wall
710: Wall breaker

Claims (7)

In a fire door including a horizontal frame 10 and a vertical frame 50, a fire cap 54 is formed on the vertical frame 50 on the side where the door hinge is installed by molding the vertical frame 50 itself, A fire door with a thermal deformation prevention function, characterized in that it includes a fixing pin (310) inserted into the fire cap (54) in the door frame (300) corresponding to the installation position of the fire cap (54).
In claim 1,
A cylinder installation groove 55 is formed in the vertical frame 50 on the side where the door cylinder is installed, and a cylinder installation groove reinforcement portion 56 is formed on the edge of the cylinder installation groove 55 by burring the vertical frame 50 itself. A fire door with a thermal deformation prevention function that is formed by
In claim 2,
Cylinder fastening hole projections 58 for screwing the door cylinder above and below the cylinder installation groove 55 of the vertical frame 50 are formed by burring the vertical frame 50 itself, and the cylinder fastening hole projections 58 A fire door with a thermal deformation prevention function that is characterized by a threaded portion formed on the inner circumferential surface.
In claim 3,
The outer bent portions 11 of the upper and lower horizontal frames 10 are formed upright on both sides of the bottom surface 16 so that the cross-section of the horizontal frame 10 forms a “└┘” shape, and a hinge 150 is installed on one side. A hinge installation end (17) is formed on the outer bent portion (11) of,
The hinge 150 includes a hinge wing portion 151 installed on the bottom surface 16 of the horizontal frame 10, and a hinge fixing portion 152 installed on the hinge installation end 17 of the outer bent portion 11. Including,
The thickness of the hinge wing portion 151 is smaller than the thickness of the hinge fixing portion 152,
A fire door with a thermal deformation prevention function, characterized in that a reinforcing pad (160) is added between the bottom surface (16) of the horizontal frame (10) and the hinge wing portion (151).
In claim 4,
A plurality of bolt insertion holes 154 for coupling with the reinforcement pad 160 and the horizontal frame 10 are formed in the hinge wing 151 of the hinge 150, and the hinge wing 151 is in the reinforcement pad 160. ) and a plurality of bolt through holes 161 for coupling with the horizontal frame 10 are formed, and a plurality of bolt fastening holes 18 for coupling with the reinforcement pad 160 are formed in the horizontal frame 10,
A fire door with a thermal deformation prevention function, characterized in that at least one of the bolt insertion hole 154 or the bolt through hole 161 is formed as a long hole to easily adjust the position at which the hinge 150 is installed on the horizontal frame 10.
In claim 5,
A fire door with a thermal deformation prevention function characterized in that the bolt fastening hole 18 of the horizontal frame 10 is formed through a burring process to form a burring protrusion, and a threaded portion is formed on the inner peripheral surface of the burring protrusion.
In claim 6,
The hinge pin support plate 170 includes a support plate bottom surface 171 supporting the lower surface of the hinge fixing part 152, and a support plate edge portion 172 in close contact with the side outline edge of the hinge fixing part 152. A fire door with an additional feature that prevents thermal deformation.